Connecting mid-board optical modules

ABSTRACT

A system for connecting a fiber optic cable to a laminate has a clip which attaches to a cover on the circuit board. The clip supports ferrules which are connected to a photonic device on the board. The clip has a backplane which supports retainers which hold the ferrules. The clip also has mating attachments for connecting to the cover. The cover additionally serves as a heat dissipator, which can include heat from the photonic device. An adapter is connected to the cover and receives the ferrules supported by the clip. The adapter connects to a standard connector, such as an LC connector. The adapter can be positioned at the edge of the laminate, or can be attached at an angle extending from an interior region of a circuit board to which the laminate is mounted.

FIELD OF THE DISCLOSURE

The present disclosure generally relates to connecting mid-board opticalmodules, and more particularly to connecting individual optical fibers,with strain relief.

BACKGROUND OF THE DISCLOSURE

Mid board optical modules (MBOs) enable moving optical I/O connectionsfrom a system faceplate directly onto a printed circuit board (PCB),enabling higher throughput and improved reliability.

There is a growing trend in the telecom, wireless, and data centermarkets to transition from copper to fiber optic networks to increasebandwidth and reduce power consumption. Within these fiber opticnetworks, optic fiber interfaces with electronic hardware at tranceivers(combined transmitters and receivers) in order to code/decode andprocess the signal. Currently, these electro-optic assemblies are madeby using a sequential process of integration of SMT (surface mounttechnology) components onto a PCB with ball grid arrays or land gridarrays, and integration of optical components onto the PCB or companionstructure.

SUMMARY OF THE DISCLOSURE

In an embodiment of the disclosure, a device for connecting a fiberoptic cable having a connector with a cable-side ferrule to a laminate,comprises at least one fixed ferrule; a clip having a backplane, atleast one retainer connected to the backplane, each of the at least oneretainer sized and dimensioned to hold one of the at least one fixedferrule in a predetermined position, and at least one clip matingattachment portion positioned upon the backplane; a cover formed with aheat conducting material, the cover including a planar portion sized anddimensioned to be positionable upon a heated component of the laminateto thereby conduct heat away from the heated component, and at least onecover mating attachment portion each mateable with one of the at leastone clip mating attachment portion to secure the clip relative to thecover in a predetermined orientation relative to the laminate; and anadapter connected to the cover and including one or more alignmentchannels each sized and dimensioned to receive a fixed ferrule supportedby one of the at least one retainer at a first end, and the cable-sideferrule at an opposite end, to thereby position the fixed ferrule andcable-side ferrule in mutual light transmitting communication.

In another embodiment of the disclosure, a device for connecting a fiberoptic cable having a connector with a cable-side ferrule to a laminate,comprises a laminate; at least one fixed ferrule; a clip having abackplane, at least one retainer connected to the backplane, each of theat least one retainer sized and dimensioned to hold one of the at leastone fixed ferrule in a predetermined position, and at least one clipmating attachment portion positioned upon the backplane; a coverconnected to the laminate, the cover formed with a heat conductingmaterial, the cover including a planar portion sized and dimensioned tobe positionable upon a heated component of the laminate to therebyconduct heat away from the heated component, and at least one covermating attachment portion each mateable with one of the at least oneclip mating attachment portion to secure the clip relative to the coverin a predetermined orientation relative to the laminate; and an adapterconnected to the cover and including one or more alignment channels eachsized and dimensioned to receive a fixed ferrule supported by one of theat least one retainer at a first end, and the cable-side ferrule at anopposite end, to thereby position the fixed ferrule and cable-sideferrule in mutual light transmitting communication.

In a further embodiment of the disclosure, a method for connecting afiber optic cable having a connector with a cable-side ferrule to alaminate, comprises connecting a cover to the laminate, the cover formedwith a heat conducting material, the cover including a planar portionsized and dimensioned to be positionable upon a heated component of thelaminate to thereby conduct heat away from the heated component, and atleast one cover mating attachment portion; and connecting a clip to thecover, the clip having a backplane, at least one retainer connected tothe backplane, each of the at least one retainer sized and dimensionedto hold a fixed ferrule in a predetermined position, and at least oneclip mating attachment portion positioned upon the backplane, each clipmating attachment portion mateable with one of the at least one covermating attachment portion to secure the clip relative to the cover in apredetermined orientation relative to the laminate; and connecting anadapter to the cover, the adapter including one or more alignmentchannels each sized and dimensioned to receive a fixed ferrule supportedby one of the at least one retainer at a first end, and the cable-sideferrule at an opposite end, to thereby position the fixed ferrule andcable-side ferrule in mutual light transmitting communication.

BRIEF DESCRIPTION OF THE DRAWINGS

Reference may be had to the accompanying figures where like referencenumerals refer to identical or functionally similar elements throughoutthe separate views, and which together with the detailed descriptionbelow are incorporated in and form part of the specification, serve tofurther illustrate various embodiments and to explain various principlesand advantages all in accordance with the present disclosure, in which:

FIG. 1 depicts a ferrule of the prior art;

FIG. 2 depicts a system of the disclosure including a laminate, clip(not visible), and adapter of the disclosure;

FIG. 3 is a top perspective view of a ferrule holding clip of thedisclosure;

FIG. 4 is a bottom perspective view of the clip of FIG. 3;

FIG. 5 is a cross section of the system of FIG. 2, taken along line A-A;

FIG. 6 is side view of the clip of FIG. 3;

FIG. 7 is a top perspective view of an alternative clip of thedisclosure;

FIG. 8 is a cutaway view of the clip of FIG. 3 connected to a covermounted to a laminate;

FIG. 9 is side view of the system of FIG. 2;

FIG. 10 is a perspective view of an alternative system of thedisclosure, including a circuit board, a cutaway of a cover, and a clip(not visible) and adapter of the disclosure;

FIG. 11 is a top perspective view of an alternative clip of thedisclosure, having an angular profile;

FIG. 12 is a bottom perspective view of the clip of FIG. 11

FIG. 13 is bisecting cross section of the system of FIG. 10;

FIG. 14 is a side view of the clip of FIG. 11;

FIG. 15 is a perspective view of the clip of FIG. 11, without ferrules;

FIG. 16 is a side view of the system of FIG. 10;

FIG. 17 is a bisecting cross section of a side view of the system ofFIG. 10;

FIG. 18 is a cutaway view of the clip of FIG. 10 connected to a covermounted to a laminate;

FIG. 19 is a perspective view of the adapter of FIG. 2;

FIG. 20 is a wireframe view of the adapter of FIG. 19;

FIG. 21 is a perspective view of a coverplate-side end of the adapter ofFIG. 2;

FIG. 22 is a perspective view of a cable side end of the adapter of FIG.2;

FIG. 23 is a perspective view of a cable side end of a single module ofan adapter of the type shown in FIG. 10;

FIG. 24 is a perspective side view showing a coverplate-side end of theadapter of FIG. 23;

FIG. 25 is a perspective side view showing a cable side end of theadapter of FIG. 23;

FIG. 26 is a perspective view of a clip of the disclosure, without ananchoring post;

FIG. 27 is a perspective view of an angled clip of the disclosure,without an anchoring post; and

FIG. 28 is a cross-sectional view of a system of the disclosure.

DETAILED DESCRIPTION OF THE DISCLOSURE

As required, detailed embodiments are disclosed herein; however, it isto be understood that the disclosed embodiments are merely examples andthat the systems and methods described below can be embodied in variousforms. Therefore, specific structural and functional details disclosedherein are not to be interpreted as limiting, but merely as a basis forthe claims and as a representative basis for teaching one skilled in theart to variously employ the present subject matter in virtually anyappropriately detailed structure and function. Further, the terms andphrases used herein are not intended to be limiting, but rather, toprovide an understandable description of the concepts.

The terms “a” or “an”, as used herein, are defined as one or more thanone. The term plurality, as used herein, is defined as two or more thantwo. The term another, as used herein, is defined as at least a secondor more. The terms “including” and “having,” as used herein, are definedas comprising (i.e., open language). The term “coupled,” as used herein,is defined as “connected,” although not necessarily directly, and notnecessarily mechanically.

The disclosure provides for integration of a two fiber LC ferruleassembly to a silicon die on a nano-photonic silicon die. Devices of thedisclosure are advantageously used for high performance servers whichrequire parallel optics transceivers, although the disclosure is alsoeffective for applications having lesser demands or which use a singlecable or more than two cables. The examples shown in the illustration,selected for clarity, are for two fiber tranceivers for lowerperformance servers, broadband home routers, and fiber to the antennasolutions.

Currently, 2 port electro-optic transceivers are often used to connect afiber optic network to an electro-optic component mounted on a laminate.A laminate is also referred to as substrate. The transceivers aredesigned to be mated with standard two fiber cable assemblies describedin the applicable fiber channel standard, which can include duplex LCs,duplex SCs, and duplex MU connectors. Although a two fiber assembly isshown and described herein, the disclosure can be applied to SC and MUconnectors having different numbers of fibers. The illustrations are forLC connectors, but the disclosure is applicable to other connectortypes.

With reference to the figures, and FIGS. 2, 5, 10, and 13 in particular,a two fiber LC assembly system 100 of the disclosure includes twooptical fibers 310 each having cleaved ends which are positioned withinand bonded into a silicon die, such as a nano-photonic silicon chip,hereinafter photonic device or die 316, which is in turn affixed on alaminate 320, in a known manner. An opposite end of each of the fibers310, 312 is installed within a ferrule 340, in the example shown an LCferrule in a known manner. While an LC ferrule is shown, other ferruletypes can be used, such as SC and MU types, or ferrule types which arehereafter developed. Ferrules 340 are installed in an adapter 200 of thedisclosure, described more particularly elsewhere herein. Adapter 200 ispositioned either at a substantially straight angle and on an edge oflaminate 320, as shown in FIG. 2, or adapter 200 is positioned at anangle to laminate 320, for further mounting of the laminate inboard, andnot along the periphery, of circuit board 328, as shown in FIG. 10.

With reference to FIGS. 1-9, a Duplex-LC connector 308 mated to twooptical cables 390, 392 is inserted into and connected to adapter 200,which is in turn optionally connected to coverplate 250. Ferrules 340are connected to adapter 200 from the opposite side of connector 308.Fibers 310 emerging from ferrules 240 are connected to photonic die 316.Photonic die 316 is affixed to laminate 320. An alignment clip 110,shown in FIGS. 3 and 4, and in cross-section in FIG. 5, supports twoferrules 340, which are not shown within clip 110 in FIGS. 3-4 forclarity, but can be seen supported in clip 112 in FIGS. 11-12 and 14, ina similar manner to clip 110. As can be seen in FIG. 1, ferrule 340includes a collar 342 which is matingly received within a snap-fitretainer 120 which surrounds more than 180 degrees of collar 342 whenferrule 340 is inserted into retainer 120. Clip 110 can be fabricatedfrom plastic or other resilient material, whereby a periphery ofretainer 120 can bend to admit passage of collar 342, and thereaftersecurely grip ferrule 340. Adhesive can be applied to collar 342 orretainer 120, particularly for high vibration environments. Ferrule 340further includes a ring 344 that is larger than collar 342 and which canbe abutted with retainer 120 to orient ferrule 340 along a longitudinalaxis that passes through clip 110 from a leading clip end 128 to atrailing clip end 140. Ring 344 further prevents longitudinal movementof ferrule 340 as a connection is made.

A backplane 118 joins two retainers 120, and orients them relative toeach other in a specific position, in this embodiment, particular to atwo fiber LC connector. While two retainers 120 are illustrated, clip110/112 can include only a single retainer 120, or more than tworetainers 120. Retainers 120 are shown connected directly to backplane118, however they can be positioned on an arm extending from oppositesides of backplane 118, extending transverse to backplane 118.

As can be seen in FIGS. 3-4, fibers 310 are each supported within aferrule 340 at one end, and can be protected and supported at anopposite end upon one or more pads 124, disposed upon backplane 118. Pad124 can include an adhesive material, or an adhesive material can beapplied, in order to maintain a position of fibers 310. Pad 124 caninclude grooves or channels 194 to faciliatate placement of fibers inpredetermined positions. The position of the fibers relative to pad 124is advantageously performed within close tolerances in order to promotean accurate placement of the fibers in the u- or v-groove of photonicdie 316. An optional lid 122 can be placed over fibers 310, on anopposite side with respect to the pads, to further secure fibers 310 inplace. Lid 122 can be UV transparent, and can be fabricated with athermoplastic material. If a UV transparent lid 122 is used, it isadvantageous for optical fibers 310 to be thermally bonded to lid 122,for example using IR selective heating or bulkheating. Fibers 310 can beplaced at a typical pitch of 250 um, 500 um or 1 mm. The position of thefibers relative to the lid is advantageously performed to closetolerances in order to promote an accurate placement of the fibers inthe u- or v-groove of photonic die 316.

A pick and place fixture can be used to place clip 110 into position forthe cleaved fiber ends, whether or not they are bonded to lid 122, to besecured into contact with photonic die 316. When lid 122 is used,advantageous material properties include optical or IR transparency inorder to support vision system placement; UV transparency in order tosupport the use of UV curable adhesives; high strength; tolerancecompliance; and having a high melt point, for example greater than about260 C. Examples of acceptable materials include FEP, PFA, and opticallyclear PEI. In a typical application, the cleaved fiber ends bonded tothe UV transparent lid will be bonded to the silicon v-groove with a UVcurable adhesive.

Clip 110 and Adapter 200 can be made from any of a variety of materials,however are advantageously formed with a glass reinforced plastic, forexample ULTEM 2300, or glass reinforced PC/PBT. The material selectedfor clip 110, in particular, advantageously can withstand temperaturesgreater than about 260 degrees C. without excessive distortion. The CTEshould be compatible with surrounding materials.

A latch 126 is formed upon a leading end 128 of backplane 118, in thisembodiment including a mating edge 130, which is engageable with adapter200 to orient backplane 118 with respect to adapter 200 with apredetermined amount of precision in order to form a proper opticalconnection, as described further elsewhere herein.

Clip 110 includes one or more mating attachment portions each sized anddimensioned to engage a mating attachment portion on cover 250. Forexample, clip 110 can include an extension, and an object secured tocover 250 can have a receiving aperture, or vice versa, so that clip 110can be secured in a fixed orientation with respect to coverplate 250 andphotonic die 316, which are in turn secured in a fixed orientation withrespect to laminate 320. In an embodiment, post 132 extends frombackplane 118 and is configured to enter a mating aperture 134 inprotective cover 250 that is secured in position relative to laminate320, thereby locating clip 110 relative to photonic die 316. A crossbar136 orients post 132 to a predetermined depth within aperture 134,thereby establishing a predetermined height of clip 110 and thus aheight of retainer 120 with respect to laminate 320, as well as ferrules340, once installed therein. Post 132 can form an interference fit withaperture 134 in order to form a secure connection with cover 250. Inaddition, or alternatively, adhesive or a fastener can be used. Post 132can also have the form of a latch, as shown and described with respectto latch 126, for example. Clip 110 can also attach to laminate 320 in asimilar manner.

Protective cover 250 attaches to laminate 320 by any known means,including adhesive and/or fasteners, and functions to protect underlyingcomponents, and to serve as a mounting point for clip 110/112, andadapter 200/207. Cover 250 can additionally dissipate heat generated byphotonic die 316, or any other component mounted to laminate 320. A heatsink 290 can be attached to one or more particular heat generatingcomponents, such as photonic die 316, and can also be attached to cover250, to transmit heat from the heat generating components to cover 250,where the heat is released into the surrounding atmosphere, athermoelectric cooling device, or a liquid cooling system. Cover 250 canbe integrally formed with heat sink 290.

Additionally, one or more retainer latches 138 extend from each retainer120, each including a mating edge 142. Latches 138 connect to cover 250,each entering an aperture 144, mating edge displacing as latch 138 isinserted into aperture 144, and resiliently springing back to anoriginal position to engage mating edge 142 with cover 250, to therebyfurther orient and secure clip 110 with respect to cover 250, and inturn with respect to laminate 320. Other means of attaching clip 110 canbe used, including adhesive. FIG. 7 illustrates clip 110 without latches138, and FIG. 26 illustrates clip 110 without post 136. Additionallyshown in FIGS. 7 and 26 are optional u- or v-grooves 194 for properlyaligning fibers 310, which can be provided on pad 124 of any embodimentherein.

In the embodiment shown, for an LC connector, ferrule 340 can have A toB spacing between ferrule centers of 6.25 mm, which matches FOCIS-10requirements. For example, fiber 310 can be ITU G.652 and G.657complaint single mode fibers. In an embodiment, fibers 310 are cleavedand spaced at, for example, a 250 um, 500 um, or 1 mm pitch, althoughthis dimension is selected to match the configuration of the silicondie/photonic die 316 V-groove (see, e.g. U.S. Patent Application2014/0270652). For other connector types, these dimensions can bedifferent.

In the embodiment of FIGS. 2-9, it can be seen that clip 110 orientsferrules 340 for engagement with adapter 200 at location adjacent to anedge of a printed circuit board 328. This minimizes the overall heightof laminate 320, and the laminate height, in particular, and does notrequire a hole or gap in printed circuit board 328 for clearance.Adapter 200, additionally shown in detail in FIGS. 19-22, joins LCconnector 308 to laminate 320, and transmits light from ferrules withinLC connector 308 to ferrules 340 supported by clip 110, to therebyenable the transmission of data to and from cables 390, 392 to photonicdie 316. Adapter 200 can be connected to laminate 320, or a componentconnected to laminate 320, such as cover 250, by any known means,including adhesive or fasteners. In the embodiment shown, adapter tabs252 lie in contact with cover 250 when adapter 200 is in a properorientation with respect to ferrules 340 held by clip 110. As can beseen in the figures, tabs 252 can be provided with mounting holes 254through which a fastener such as a screw can be passed to connectadapter 200 to cover 250, although tabs 252 can be adhered to cover 250or another component connected to laminate 320. Clip 110 can have az-axis profile of, for example, an ‘L’ shape, or any otherconfiguration, to accommodate off axis assembly.

In the example of FIGS. 2 and 19-22, adapter 200 has two modules 260into which a duplex LC connector can be inserted. However, it should beunderstood that a greater or fewer number of modules 260 can be formed,or multiple separate adapters 200 can be placed side by side inconnection with coverplate 250 or laminate 320, each adapter having asingle module 260, such as is shown for an angled adapter 270 in FIGS.23-25, described elsewhere herein.

As may be seen in FIGS. 19-24, each module 260 of either adapter 200 oradapter 270 accepts insertion of an LC connector on a connector end 262,and ferrule 340 at a board end 264. As can be seen in the wire framemodel of FIG. 20, an alignment channel 266 within an interior of adapter200 admits insertion of ferrule 340, which is fixed in a position withrespect to photonic die 316, and a cable-side ferrule within the LCconnector, to align the fixed and cable-side ferrules for datacommunication. In an embodiment, a ceramic split sleeve is installed inthe alignment channel, which centralizes ferrules from both sides. Tabs252 align adapter 200/270 with clip 110 and therefore align ferrule 340with alignment channel 266. An interior chamber 268 within module 260 isconfigured to align and orient the type of connector for which adapter220/270 is intended for use with system 100, and can include a catchstructure 272 which can mate with a latch structure of the connector,including that of the LC connector.

With reference to FIG. 2, and to FIG. 5, which is a cross-section ofFIG. 2 taken along line A-A, two optical cables 390, 392 are terminatedin a duplex LC connector 308, the connector inserted into chambers 268,and a ferrule of the LC connector is inserted into alignment channel 266of adapter 200/276. Clip 110 is connected to adapter 200 at latch 126,and to cover 250 at post 132. In addition, lid 122 has been positionedwith respect to a u- or v-groove, or other alignment structure, ofphotonic die 316, thereby positioning fibers 310 with respect tophotonic die 316.

In this manner, cable 392 is aligned with a ferrule within LC connector308, the connector ferrule is aligned with ferrule 340 within adapter200, adapter 200 is aligned with respect to cover 250 and laminate 320,clip 110 is aligned with adapter 200 and cover 250, and fibers 310 arealigned with photonic die 316, whereby light transmission and datacommunication can effectively take place between cables 390, 392 andphotonic die 316.

Likewise, strain relief is transferred from cable 390 or 392 through theLC latch to adapter 200/207, and from adapter 200 via tab 252 oradhesive to cover 250, and via cover 250 to laminate 320, the lattertypically connected to a printed circuit board that is in turn connectedto a chassis. In this manner, no stress is imparted to fibers 310 fromstress applied to cables 390 or 392.

It should further be understood that adapter 200/207 can be connected tolaminate 320 in addition to, or in the alternative to, attachment tocover 250, using tabs, adhesive, or other method of attachment.

With reference to FIGS. 10-17, an alternative embodiment of thedisclosure enables connection to an optical cable at a location notalong an edge, but to an interior region of an electronic printedcircuit board 328, where laminate 320 and photonic die 316 are attached.To ensure space for insertion of connector 308 among componentspositioned upon laminate 320, clip 112, adapter 207, and ferrules 340are angled upwards and away from a surface of laminate 320, so that aconnector 308 can be angularly inserted into adapter 200/207. Clip 112is analogous to clip 110, however backplane 158 has a bend 152 causingleading end 128 of clip 112 to be raised, and retainers 120 to bepositioned at an angle with respect to a plane defined by photonic die316. In this manner, clip end 140 is parallel to a plane defined by theu- or v-grooves of photonic die 316, and therefore pads 124 and lid 122function as described with respect to clip 110, however ferrules 340 areheld to angle upwards and away from this plane. The angle can be chosento avoid interference with components on laminate 320, as well as todefine a curved exit path for cable 390, 392 without sharp bends.Laminate 320 serves to connect photonic die 316 to a PCB 328, and alsoserves for improving heat dissipation at a board-side location.

In addition to latch 126, clip 112 is attached to system 100 and held inposition by clip tab 160, which includes a mounting hole 162 throughwhich a fastener or adhesive can be passed. Clip tab 160 is oriented tobe coplanar with cover 250 when clip 112 is installed, to thereby definea correct predetermined angular orientation of bend 152 and clip 112. Asclip 112 is not positioned under cover 250 to the extent shown for clip110, latches 138 are not provided.

Adapter 207 is analogous to adapter 200, however adapter tabs 282 arepositioned at an angle with respect to a body of the adapter, or withrespect to adapter tabs 252 of adapter 200, to thereby position adapter207 at the same angle as ferrules 340 when adapter 207 is connected tocover 250. A guide flange 296 can be provided, at a right angle to tab282, to abut cover 250 when installed to align and stabilize aconnection between adapter 207 and cover 250. Adapter 207 is fastened tocover 250 in a like manner as adapter 200, and otherwise functions asdescribed with respect to adapter 200.

In FIG. 26, an embodiment of clip 110 is formed as described withrespect to clip 110 of FIGS. 3-4, however clip 110 of FIG. 26 does notinclude post 132 or latches 138. As can be seen in FIG. 28, clip 110 isfastened directly to cover 250, for example using an adhesive. Clip 112of FIG. 27 is formed as described with respect to clip 112 of FIG.11-12, however as in FIG. 26, the anchoring member has been removed,specifically, clip tab 160. As with the embodiment of FIG. 28, clip 112of FIG. 27 can be adhered to cover 250, or any other part which is fixedwith respect to photonic die 316.

It should be understood that while anchors 132, 138, and 160 can beabsent, they can also be present in a different form than as shownherein. More particularly, each cover 250 or other part to which clip110/112 is to be attached can have a different shape, and it should beunderstood that anchors 132, 138, and 160 can likewise have a particularcorresponding shape. A greater or fewer number of anchors canalternatively be provided upon clip 110/112.

An alternative cover 250 shape is shown in FIG. 28, conformed to thecomponents it is protecting. FIG. 28 additionally illustrates photonicdie 316 electrically connected to a micro-electronic chip 358 throughlaminate 320.

The disclosure thus provides a substantially lower cost connection to aphotonic die 316 than heretofore known, and provides a compact formfactor. The disclosure combines the functionality of SMT, ball gridarrays, and optical components in one assembly method. The disclosureadditionally interfaces with standard 2F fiber optic cable assemblies,and can be environmentally sealed for OSP applications. The disclosurefurther provides a low power consumption solution with a reduced numberof components.

What is claimed is:
 1. A device for connecting a fiber optic cablehaving a connector with a cable-side ferrule to a photonic device,comprising: at least one fixed ferrule; a clip having a backplane, atleast one retainer connected to the backplane, each of the at least oneretainer sized and dimensioned to hold one of the at least one fixedferrule in a predetermined position, and a cover formed with a heatconducting material, the cover including a planar portion sized anddimensioned to be positionable upon a heated component of the photonicdevice to thereby conduct heat away from the heated component, the clipconnected to the cover, and an adapter positioned with respect to thecover and including one or more alignment channels each sized anddimensioned to receive a fixed ferrule supported by one of the at leastone retainer at a first end, and the cable-side ferrule at an oppositeend, to thereby position the fixed ferrule and cable-side ferrule inmutual light transmitting communication.
 2. The device of claim 1,further including a light transmitting fiber connected to each of the atleast one fixed ferrule and extending away from the fixed ferrule tocontact an attachment point on the backplane.
 3. The device of claim 2,wherein each of the light transmitting fibers is connected at an endopposite the end connected to the fixed ferrule to a photonic die. 4.The device of claim 2, wherein the cover covers a photonic die connectedto the light transmitting fiber connected to each of the at least onefixed ferrule.
 5. The device of claim 1, wherein the adapter ispositioned at one of the edge of the laminate and an interior region ofa circuit board upon which the laminate is mounted.
 6. The device ofclaim 1, further including a light transmitting fiber connected to eachof the at least one fixed ferrule and extending away from the fixedferrule and secured in a predetermined orientation to a lid, the lidconfigured to be positionable upon a photonic die connected to thelaminate.
 7. The device of claim 6, wherein each of the lighttransmitting fibers contact an attachment point on the backplane.
 8. Thedevice of claim 6, wherein the lid is UV transparent and the lighttransmitting fibers are secured to the lid with a UV curable adhesive.9. The device of claim 6, wherein the clip includes grooves for aligningthe light transmitting fibers.
 10. The device of claim 6, wherein theclip has a melting point greater than 260 degrees C.
 11. The device ofclaim 1, wherein the clip mating attachment portion is a post, and thecover mating attachment portion is an aperture.
 12. The device of claim1, wherein the clip and the adapter are mutually connected by respectivemating latching portions.
 13. The device of claim 1, wherein the adapterfurther includes a chamber sized and dimensioned to matingly receive theconnector.
 14. The device of claim 13, wherein the connector type isselected from LC, SC, MU, duplex LC, duplex SC, and duplex MU.
 15. Thedevice of claim 1, wherein the backplane is bent to form a first portionthat is coplanar with a board plane that is defined by a surface of thelaminate, and a second portion, including the at least one retainer,that extends away from the surface of the laminate at an angle withrespect to the board plane, each of the at least one retainers therebypositioned to support a fixed ferrule at a predetermined angle withrespect to the board plane.
 16. The device of claim 15, wherein theadapter is connected to the cover with a tab that forms an angle with abody of the adapter corresponding to the predetermined angle.
 17. Thedevice of claim 15, wherein the clip mating portion is a tab extendingfrom the backplane at an angle that is coplanar with the first portionof the backplane.
 18. The device of claim 1, wherein the cover is fixedin a position relative to the laminate, the clip fixed in a positionrelative to the laminate, the clip further including at least one clipmating attachment portion, and the cover further including at least onecover mating attachment portion connectable to the at least one clipmating attachment portion.
 19. A device for connecting a fiber opticcable having a connector with a cable-side ferrule to a photonic device,comprising: a laminate; a photonic die affixed to the laminate; at leastone fixed ferrule; a clip having a backplane, at least one retainerconnected to the backplane, each of the at least one retainer sized anddimensioned to hold one of the at least one fixed ferrule in apredetermined position, and a cover connected to the laminate, the coverformed with a heat conducting material, the cover including a planarportion sized and dimensioned to be positionable upon a heated componentof the laminate to thereby conduct heat away from the heated component;and an adapter positioned with respect to the cover and including one ormore alignment channels each sized and dimensioned to receive a fixedferrule supported by one of the at least one retainer at a first end,and the cable-side ferrule at an opposite end, to thereby position thefixed ferrule and cable-side ferrule in mutual light transmittingcommunication.
 20. A method for connecting a fiber optic cable having aconnector with a cable-side ferrule to a laminate, comprising:connecting a cover to the laminate, the cover formed with a heatconducting material, the cover including a planar portion sized anddimensioned to be positionable upon a heated component of the laminateto thereby conduct heat away from the heated component; and connecting aclip to the cover in a predetermined orientation relative to thelaminate, the clip having a backplane, at least one retainer connectedto the backplane, each of the at least one retainer sized anddimensioned to hold a fixed ferrule in a predetermined position; andpositioning an adapter with respect to the cover, the adapter includingone or more alignment channels each sized and dimensioned to receive afixed ferrule supported by one of the at least one retainer at a firstend, and the cable-side ferrule at an opposite end, to thereby positionthe fixed ferrule and cable-side ferrule in mutual light transmittingcommunication.